CN110212944B - I-type concentrator routing communication module batch detection device and detection method thereof - Google Patents

Abstract

The invention provides a batch detection device for route communication modules of I-type concentrators, which is characterized in that a main control cabinet is provided with a three-phase adjustable control power supply module, a main control computer module, an external input module, a key control module, a power consumption test module, an HPLC broadband carrier test module, a strong and weak electric interface and an external interface, the upper end of an epitope test bench is provided with a plurality of single-module test epitopes, the single-module test epitopes are provided with indicator lamps, the main control cabinet is connected with the epitope test bench through communication cables of the strong and weak electric interface, the three-phase adjustable control power supply module is electrically connected with the main control computer module and is controlled by the main control computer module to output power, the key control module is electrically connected with the three-phase adjustable control power supply module, and the HPLC broadband carrier test module and the power consumption test module are electrically connected with the main control computer module. The invention also provides a batch detection method of the concentrator routing communication module. The invention can detect the overall performance of HPLC broadband carrier in batches.

Description

I-type concentrator routing communication module batch detection device and detection method thereof

Technical Field

The invention relates to the technical field of communication module detection, in particular to a batch detection device and a detection method for I-type concentrator routing communication modules.

Background

At present, downlink communication of the electric power and electric quantity collection equipment is generally carried out in a carrier communication mode, along with popularization of an HPLC broadband carrier communication technology in the power grid, a downlink carrier communication module is gradually replaced by a narrowband carrier module, and along with full coverage of electric power collection, the number of HPLC broadband carrier is increased. At present, the HPLC broadband carrier detection is mainly carried out by manually carrying out single function on a single module through single equipment, the batch detection cannot be carried out, the detection time is long, and the efficiency is low, so that the batch and large-scale production requirements cannot be met.

Disclosure of Invention

The invention aims to provide a batch detection device and a detection method for an I-type concentrator routing communication module, which can be used for detecting the overall performance of HPLC broadband carriers in batches.

In order to achieve the above purpose, the invention adopts the following technical scheme: the utility model provides a I type concentrator route communication module batch detection device, includes master control cabinet and epitope testboard, be equipped with three-phase adjustable control power module, master control computer module, external input module, button control module, power consumption test module, HPLC broadband carrier test module, strong and weak electric interface and external interface on the master control cabinet, master control cabinet and epitope testboard's lower extreme is equipped with the universal wheel, the upper end of epitope testboard is equipped with a plurality of single module test epitope, be equipped with the pilot lamp on the single module test epitope, carry out communication cable connection through strong and weak electric interface between master control cabinet and the epitope testboard, three-phase adjustable control power module is connected with master control computer module electricity and is controlled power output by master control computer module, button control module is connected with three-phase adjustable control power module electricity, HPLC broadband carrier test module is all connected with master control computer module electricity with power consumption test module.

Further, establish the slot in the single module test epitope, first limit socket is installed to the interior bottom of slot, be equipped with light current socket in the first limit socket, light current socket is equipped with first current conducting plate at epitope testboard up end, first current-carrying pole is installed to first current conducting plate one end of keeping away from first limit socket, second limit socket is still installed to the interior bottom of slot, be equipped with strong current socket in the second limit socket, strong current socket is equipped with the second current conducting plate at epitope testboard up end, the second current-carrying pole is installed to second current conducting plate one end of keeping away from second limit socket.

Further, first piston is all installed to one side that first limit sleeve inner wall is relative, first piston axle is installed to first piston one end of keeping away from first limit sleeve, the second piston is installed to first piston axle one end of keeping away from first piston, the second elasticity limiting plate is installed to second piston one end of keeping away from first piston axle, be equipped with the second spring between first piston and the second piston, the second spring cup joints the periphery at first piston axle.

Further, the second hinge is arranged on the inner wall of the slot of the epitope test board, the first elastic limiting plate is arranged on the second hinge, and a first spring is arranged on one side wall, close to the epitope test board, of the first elastic limiting plate.

Further, the third piston is installed to one side that the second limit sleeve inner wall is relative, the second piston axle is installed to one side that the second limit sleeve was kept away from to the third piston, the fourth piston is installed to one side that the second piston axle was kept away from to the second piston, the third elasticity limiting plate is installed to one side that the fourth piston was kept away from the second piston axle, be equipped with the second spring between third piston and the fourth piston, the second spring cup joints the periphery at the second piston axle.

Furthermore, the measured module is pegged graft outward to the slot, the weak current interface contact pin of measured module, the strong current socket contact pin of measured module and iron plate mounting panel are installed to the one side that is close to the slot of measured module, install the iron plate on the iron plate mounting panel, bottom and install magnet on the epitope testboard in the slot.

Further, the length of the weak current interface contact pin of the tested module and the length of the strong current socket contact pin of the tested module are h2, the distance between the iron block and the lower end face of the tested module is h3, h2=h3, and the depths of the weak current socket and the strong current socket are smaller than h2.

Furthermore, a concave part is arranged on the periphery of the tested module, an extension part is formed on the tested module by the concave part, the depth of the concave part is h1, and the depth of the slot is h4, wherein h4 is less than h1.

Further, a first hinge is arranged on the epitope test board, a cover plate is arranged on the first hinge, and a handle is arranged on the cover plate.

The invention also provides a batch detection method of the I-type concentrator routing communication module, which comprises the following steps:

s1, inserting a tested module into a slot, then contacting with a first conductive plate through a weak electric interface pin of the tested module, connecting with a main control computer module on a main control cabinet through a strong and weak electric interface through a first electrifying rod, contacting with a second conductive plate through a strong electric interface pin of the tested module, and connecting with the main control computer module on the main control cabinet through a second conductive rod;

s2, controlling the output power of the three-phase adjustable control power supply module through the key control module, and supplying power to the power consumption testing module, the HPLC broadband carrier testing module and the single-module testing meter by the output power to realize the HPLC broadband carrier routing communication testing and the power consumption testing of the tested module;

s3, the indicator lamps are three red and green double-color status indicator lamps, namely a module installation information indicator lamp, an HPLC broadband carrier route test status indicator lamp and a power consumption test status indicator lamp respectively, when the module installation information indicator lamp is on, the green indicator module is installed in place and well contacted, the red indicator module is installed abnormally, the HPLC broadband carrier route test status indicator lamp is on, the bright green color indicates that the HPLC broadband carrier route communication test item is qualified, and the bright red color indicates that the HPLC broadband carrier route communication test item is unqualified; the power consumption test state indicator lights are on green to indicate that the power consumption test items are qualified, and on red to indicate that the power consumption test items are not qualified.

After the technical scheme is adopted, the tested module is inserted into the slot, then contacts with the first conducting plate through the weak electric interface pin of the tested module, then is connected with the main control computer module on the main control cabinet through the strong and weak electric interface through the first electrifying rod, contacts with the second conducting plate through the strong and weak electric interface pin of the tested module, is connected with the main control computer module on the main control cabinet through the second conducting rod, then controls the three-phase adjustable control power supply module to output power through the key control module, and the output power supplies power to the power consumption test module, the HPLC broadband carrier test module and the single module test epitope to realize the HPLC broadband carrier route communication test and the power consumption test of the tested module; the power consumption test state indicator light is bright green and indicates that the power consumption test item is qualified, and bright red indicates that the power consumption test item is unqualified, and as a plurality of single-module test epitopes are arranged on the epitope test bench, the overall performance of the HPLC broadband carrier wave can be detected in batches, and the HPLC broadband carrier wave power consumption test and the HPLC broadband carrier wave communication test can be met. The testing process is fully automatic, and batch detection is performed. The detection efficiency and the primary detection accuracy can be effectively provided, and the human factor interference is reduced. The use of the detection device can greatly provide the capacity and the working efficiency of the HPLC broadband carrier.

Other features and advantages of the present invention will be disclosed in the following detailed description of the invention and the accompanying drawings.

Drawings

The invention is further described below with reference to the accompanying drawings:

fig. 1 is a schematic structural diagram of a batch detection device for a routing communication module of an I-type concentrator according to the present invention;

FIG. 2 is a partial cross-sectional view of a single module test epitope in a batch inspection device for I-type concentrator routing communication modules in accordance with the present invention;

FIG. 3 is an enlarged partial schematic view of FIG. 2A;

FIG. 4 is an enlarged partial schematic view at B in FIG. 2;

FIG. 5 is an enlarged partial schematic view of FIG. 2 at C;

fig. 6 is a partial top view of a single module test epitope in a batch detection device for routing communication modules of an I-type concentrator according to the present invention.

Detailed Description

The invention will be further described with reference to the drawings and the specific examples. It is to be understood that the terms "upper," "lower," "left," "right," "longitudinal," "transverse," "inner," "outer," "vertical," "horizontal," "top," "bottom," and the like, as used herein, are merely based on the orientation or positional relationship shown in the drawings and are merely for convenience in describing the present invention and to simplify the description, and do not indicate or imply that the devices/elements referred to must have or be configured and operated in a particular orientation and therefore should not be construed as limiting the invention.

As shown in fig. 1-6, the invention provides a batch detection device for routing communication modules of an I-type concentrator, which comprises a main control cabinet 1 and an epitope test bench 2, wherein a three-phase adjustable control power supply module 3, a main control computer module 4, an external input module 5, a key control module 7, a power consumption test module 8, an HPLC broadband carrier test module 9, a strong and weak electric interface 11 and an external interface 12 are arranged on the main control cabinet 1, the epitope test bench 2 is provided with universal wheels 6 at the lower ends, a plurality of single-module test epitopes 13 are arranged at the upper ends of the epitope test bench 2, an indicator lamp 46 is arranged on the single-module test epitopes 13, the main control cabinet 1 and the epitope test bench 2 are connected through a communication cable by the strong and weak electric interface 11, the three-phase adjustable control power supply module 3 is electrically connected with the main control computer module 4, the main control computer module 4 controls power supply output, the key control module 7 is electrically connected with the three-phase adjustable control power supply module 3, and the HPLC broadband carrier test module 9 and the power consumption test module 8 are electrically connected with the main control computer module 4.

It can be understood that the main control cabinet 1 is made of metal materials, and the safety of the use of the main control cabinet 1 is ensured through the grounding wire grounding arrangement.

Meanwhile, the key control module 7 is composed of a group of four keys, and comprises an operation key, a start key, a stop key and a reset key, wherein an external power supply of the start key control device is powered off, the operation key control device is in an operation state, the stop key control device is in a stop operation state, and a software part of the reset key control device is initialized to reset.

The main control computer module 4 is provided with a complete set of automatic detection software of the HPLC broadband carrier module, the software supports multithread batch detection, and can complete full-automatic detection of test items such as power consumption test, HPLC broadband carrier communication test and the like; the main control computer module 4 is in data communication with the HPLC broadband carrier test module 9 and the power consumption test module 8 through serial ports.

The external input module 5 provides external signal input for the main control computer module 4, including a mouse and a keyboard.

The HPLC broadband carrier test module 9 is internally provided with 8 analog carrier electric energy meters with HPLC broadband carriers. The corresponding test can be completed by automatically selecting the analog carrier electric energy meter corresponding to the matched HPLC broadband carrier according to the tested concentrator HPLC broadband carrier route or by software.

The power consumption test module 8 supports the single module test meter 13 to independently acquire module power consumption. Multithreading communication saves test time; and calculating module power consumption by reading the single-table module power parameter, comparing the module power consumption with a power consumption threshold value, and judging whether the power consumption is qualified or not. The power consumption testing module 8 is in data communication with the main control computer module 4 through a serial port.

All the communication among the strong and weak electric interface 11, the main control cabinet 1 and the epitope test bench 2 is carried out through the strong and weak electric interface 11. The strong and weak electrical interface 11 supports a multi-threaded serial communication mode.

The external interface 12 is composed of 2 sets of USB input-output signals and a path of serial port debug signals. And external USB standard equipment is supported. The device can be used for externally connecting USB equipment such as an infrared code scanning gun and the like, and improves the working efficiency.

The epitope test bench 2 comprises 60 independent single-module test epitopes 13, and universal wheels 6 are arranged at the lower ends of the main control cabinet 1 and the epitope test bench 2, so that the epitope test bench is convenient to move.

In a specific test process, the method comprises the following steps:

s1, a tested module 17 is inserted into a slot 10, then is contacted with a first conductive plate 25 through a tested module weak current interface pin 20, then is connected with a main control computer module 4 on a main control cabinet 1 through a first power-on pole 26 and a strong and weak current interface 11, is contacted with a second conductive plate 29 through a tested module strong current interface pin 21, and is connected with the main control computer module 4 on the main control cabinet 1 through a second conductive pole 28;

s2, controlling the three-phase adjustable control power supply module 3 to output power through the key control module 7, and supplying power to the power consumption test module, the HPLC broadband carrier test module and the single module test table 13 by the output power to realize the HPLC broadband carrier route communication test and the power consumption test of the tested module 17;

s3, the indicator lamp 46 is three red and green double-color status indicator lamps which are respectively a module installation information indicator lamp, an HPLC broadband carrier wave routing test status indicator lamp and a power consumption test status indicator lamp, when the module installation information indicator lamp is on, the green indicator module is installed in place and is in good contact, the red indicator module is installed abnormally, the HPLC broadband carrier wave routing test status indicator lamp is on, the HPLC broadband carrier wave routing communication test item is qualified, and the on red indicator HPLC broadband carrier wave routing communication test item is unqualified; the power consumption test state indicator lights are on green to indicate that the power consumption test items are qualified, and on red to indicate that the power consumption test items are not qualified.

In this embodiment, the slot 10 is disposed in the single-module test epitope 13, the first limiting sleeve 34 is mounted at the inner bottom of the slot 10, the weak current socket 24 is disposed in the first limiting sleeve 34, the first conductive plate 25 is disposed at the upper end face of the epitope test bench 2 in the weak current socket 24, the first conductive plate 25 is disposed at one end far away from the first limiting sleeve 34, the first conductive rod 26 is mounted at the inner bottom of the slot 10, the second limiting sleeve 40 is further mounted at the inner bottom of the slot 10, the strong current socket 30 is disposed in the second limiting sleeve 40, the second conductive plate 29 is disposed at the upper end face of the epitope test bench 2 in the strong current socket 30, and the second conductive rod 28 is mounted at one end far away from the second limiting sleeve 40 in the second conductive plate 29. The tested module 17 is inserted into the slot 10, the tested module weak current interface pin 20 is in contact with the first conductive plate 25 through the clamping fit of the first limit sleeve 34 at the weak current socket 24 and the tested module weak current interface pin 20, then the tested module strong current interface pin 21 is in conductive connection with the second limit sleeve 40 at the strong current socket 30 through the first conductive rod 26, and the tested module strong current interface pin 21 is in conductive connection with the second conductive plate 29 through the second conductive rod 28 after the tested module strong current interface pin 21 is in contact with the weak current socket, so that the strong current pin and the weak current pin of the tested module 17 can be stably inserted into the strong and weak current socket, the plugging stability of the tested module 17 is greatly improved, and the efficiency and the accuracy of single-module testing are improved.

In this embodiment, the opposite sides of the inner wall of the first limiting sleeve 34 are respectively provided with a first piston 35, one end of the first piston 35 far away from the first limiting sleeve 34 is provided with a first piston shaft 36, one end of the first piston shaft 36 far away from the first piston 35 is provided with a second piston 38, one end of the second piston 38 far away from the first piston shaft 36 is provided with a second elastic limiting plate 39, a second spring 37 is arranged between the first piston 35 and the second piston 38, and the second spring 37 is sleeved on the periphery of the first piston shaft 36. The first piston 35, the first piston shaft 36 and the second piston 38 are arranged on the opposite side of the inner wall of the first limit sleeve 34, the second elastic limit plate 39 is arranged at one end, far away from the first piston shaft 36, of the second piston 38, the first piston shaft 36 stretches and contracts in the first piston 35 and the second piston 38, the second spring 37 is sleeved on the periphery of the first piston shaft 36, when the second elastic limit plate 39 is extruded, the expansion and contraction of the first piston shaft 36, the first piston 35, the second piston 38 and the second spring 37 can be buffered, and the second spring 37 has elastic restoring force, so that the second elastic limit plate 39 can generate reverse extrusion force, and the stability of mounting the contact pin is improved.

In this embodiment, the epitope test board 2 is provided with a second hinge 31 on the inner wall of the slot 27, a first elastic limiting plate 32 is provided on the second hinge 31, and a first spring 33 is provided on a side wall of the first elastic limiting plate 32 near the epitope test board 2. Through installing the second hinge 31 on the inside wall of slot 27 at epitope testboard 2, install first elasticity limiting plate 32 on the hinge 31 to at first elasticity limiting plate 32 and be close to epitope testboard 2 a side wall installation first spring 33, by first elasticity limiting plate 32 and the contact of module 17 outer wall that is surveyed, transmit extrusion force to first spring 33 after first elasticity limiting plate 32 receives the extrusion, the direction extrusion force to module 17 that is surveyed is realized to the elasticity restoring force of first spring 33 self, thereby improved the stability to the installation of module 17 that is surveyed.

In this embodiment, the opposite sides of the inner wall of the second limiting sleeve 40 are respectively provided with a third piston 41, one side, away from the second limiting sleeve 40, of the third piston 41 is provided with a second piston shaft 42, one side, away from the third piston 41, of the second piston shaft 42 is provided with a fourth piston 44, one side, away from the second piston shaft 42, of the fourth piston 44 is provided with a third elastic limiting plate 45, a second spring 43 is arranged between the third piston 41 and the fourth piston 44, and the second spring 43 is sleeved on the periphery of the second piston shaft 42. By expanding and contracting between the third piston 41 and the fourth piston 44 at the second piston shaft 42 and utilizing the elastic restoring force of the second spring 43, the reverse extrusion force of the third elastic limiting plate 45 to the tested module 17 is realized when the third elastic limiting plate 45 is extruded, thereby improving the stability of the installation of the tested module 17.

In this embodiment, the tested module 17 is plugged outside the slot 10, the tested module weak current interface pin 20, the tested module strong current socket pin 21 and the iron block mounting plate 22 are installed on one side of the tested module 17 close to the slot 10, the iron block 23 is installed on the iron block mounting plate 22, and the magnet 27 is installed at the bottom inside the slot 10 and on the epitope test bench 2. After the tested module 17 is inserted into the slot 10, the iron block 23 is contacted with the magnet 27 to realize attraction, so that the installation firmness of the tested module 17 is further improved, and the test stability of the tested module 17 is ensured.

In this embodiment, the lengths of the weak current interface pin 20 of the tested module and the strong current socket pin 21 of the tested module are h2, the distance between the iron block 23 and the lower end surface of the tested module 17 is h3, h2=h3, and the depths of the weak current socket 24 and the strong current socket 30 are smaller than h2. The length of the contact pin is the same as the interval between the iron block 23 and the lower end face of the tested module 17, so that the iron block 23 and the magnet 27 can be smoothly contacted and then attracted, and the depths of the weak current socket 24 and the strong current socket 30 are smaller than h2 so as to avoid the situation that the iron block 23 and the magnet 27 cannot be contacted and attracted due to the fact that the limiting sleeve is abutted against the lower end face of the tested module.

In this embodiment, the outer periphery of the module under test 17 is provided with a recess 18, the recess 18 forms an extension 19 on the module under test 17, the depth of the recess 18 is h1, and the depth of the slot 10 is h4, h4 < h1. It can be ensured that a gap is left between the tested module 17 and the epitope test bench 2 after the tested module 17 is inserted into the slot 10, and the tested module 17 can be conveniently taken out.

In this embodiment, the first hinge 14 is mounted on the epitope test stand 2, the cover plate 15 is mounted on the first hinge 14, and the handle 16 is mounted on the cover plate 15. The cover plate 15 can cover the slot 10 when the test is not needed, so that dust and water are prevented from entering to damage the epitope test table 2, and the service life of the device is prolonged.

It will be appreciated that the epitope test bench 2 is of an inclined design, which facilitates the insertion and removal of the module under test 17 and the observation of the test results.

In addition to the above preferred embodiments, the present invention has other embodiments, and various changes and modifications may be made by those skilled in the art without departing from the spirit of the invention, which is defined in the appended claims.

Claims (7)

1. The device is characterized by comprising a main control cabinet and an epitope test bench, wherein the main control cabinet is provided with a three-phase adjustable control power supply module, a main control computer module, an external input module, a key control module, a power consumption test module, an HPLC broadband carrier test module, a strong and weak electric interface and an external interface, universal wheels are arranged at the lower ends of the main control cabinet and the epitope test bench, a plurality of single-module test epitopes are arranged at the upper ends of the epitope test bench, indicator lamps are arranged on the single-module test epitopes, the main control cabinet and the epitope test bench are connected through communication cables through the strong and weak electric interface, the three-phase adjustable control power supply module is electrically connected with the main control computer module and is controlled by the main control computer module to output power, the key control module is electrically connected with the three-phase adjustable control power supply module, the HPLC broadband carrier test module and the power consumption test module are electrically connected with the main control computer module, a slot is arranged in the single module test meter position, a first limit sleeve is arranged at the inner bottom of the slot, a weak current socket is arranged in the first limit sleeve, a first conductive plate is arranged at the upper end face of the meter position test table and far away from the first limit sleeve, a first through rod is arranged at one end of the first conductive plate, a second limit sleeve is also arranged at the inner bottom of the slot, a strong current socket is arranged in the second limit sleeve, a second conductive plate is arranged at the upper end face of the meter position test table and far away from one end of the second limit sleeve, a first hinge is arranged on the meter position test table, a cover plate is arranged on the first hinge, and a handle is arranged on the cover plate.

2. The batch detection device for the routing communication modules of the I-type concentrators according to claim 1, wherein the first pistons are arranged on the opposite sides of the inner wall of the first limiting sleeve, a first piston shaft is arranged at one end, far away from the first limiting sleeve, of the first pistons, a second piston is arranged at one end, far away from the first pistons, of the first piston shaft, a second elastic limiting plate is arranged at one end, far away from the first piston shaft, of the second pistons, a second spring is arranged between the first pistons and the second pistons, and the second spring is sleeved on the periphery of the first piston shaft.

3. The batch detection device for the routing communication modules of the I-type concentrator of claim 2, wherein the epitope test board is provided with a second hinge on the inner wall of the slot, the second hinge is provided with a first elastic limiting plate, and a side wall of the first elastic limiting plate, which is close to the epitope test board, is provided with a first spring.

4. The batch detection device for the routing communication modules of the I-type concentrators according to claim 1, wherein the third pistons are arranged on the opposite sides of the inner wall of the second limiting sleeve, the second piston shaft is arranged on the side, far away from the second limiting sleeve, of the third pistons, the fourth pistons are arranged on the side, far away from the third pistons, of the fourth pistons, the third elastic limiting plate is arranged on the side, far away from the second piston shaft, of the fourth pistons, and a second spring is arranged between the third pistons and the fourth pistons and is sleeved on the periphery of the second piston shaft.

5. The batch detection device for I-type concentrator routing communication modules according to claim 1, wherein the detected modules are inserted outside the slots, weak current interface pins of the detected modules, strong current socket pins of the detected modules and an iron block mounting plate are mounted on one side of the detected modules, which is close to the slots, iron blocks are mounted on the iron block mounting plate, and magnets are mounted at the bottoms in the slots and on the epitope test board.

6. The batch detection device for the routing communication modules of the type I concentrator of claim 5, wherein the weak current interface pins of the detected module and the strong current socket pins of the detected module are h2, the distance between the iron block and the lower end surface of the detected module is h3, h2=h3, and the depths of the weak current sockets and the strong current sockets are smaller than h2.

7. The batch inspection device for I-type concentrator routing communication modules of claim 5, wherein the outer periphery of the inspected module is provided with a concave portion, the concave portion forms an extension portion on the inspected module, the depth of the concave portion is h1, and the depth of the slot is h4, wherein h4 is less than h1.